JP6861780B2 - Wireless network nodes, wireless devices, and how they are performed - Google Patents

Description

The present embodiment relates to wireless network nodes, wireless devices, and methods performed in them for wireless communication. In addition, computer programs and computer readable storage media are also provided. In particular, the present embodiment relates to processing data communication such as data transmission to a wireless network node in a wireless communication network.

In a typical radio communication network, a radio device, also known as a radio communication device, mobile station, station (STA) and / or user equipment (UE), is one or more via a radio access network (RAN). Communicate with the core network (CN). The RAN covers a geographical area divided into service areas or cell areas. The area is also referred to as a beam or beam group, and each service area or cell area is a radio such as a Wi-Fi access point or a radio base station, which in some networks may also be referred to as a "NodeB" or "eNodeB". Services are provided by network nodes. A service area or cell area is a geographic area where wireless coverage is provided by a wireless network node. The wireless network node communicates with wireless devices within the range of the wireless network node via an air interface operating on the wireless frequency.

UMTS is a third-generation (3G) communication network that has evolved from the second-generation (2G) global system for mobile communications (GSM). UMTS Radio Access Network (UTRAN) is essentially a RAN that uses Broadband Code Division Multiple Access (WCDMA) and / or High Speed Packet Access (HSPA) for user equipment. At the forum, known as the 3rd Generation Partnership Project (3GPP), telecommunications suppliers have proposed and agreed on standards for 3rd generation networks and are considering improving data rates and wireless capacities. In some RANs, multiple wireless network nodes, such as UMTS, can be connected to controller nodes, such as a wireless network controller (RNC) or base station controller (BSC), for example by landline or microwave. It can monitor and coordinate various activities of multiple wireless network nodes connected to it. This type of connection is sometimes referred to as a backhaul connection. The RNC and BSC are typically connected to one or more core networks.

The evolutionary packet system (EPS) specification, also known as the 4th generation (4G) network, has been completed within 3GPP, and this work will continue to specify future 3GPP releases, such as the 5th generation (5G) network. ing. EPS is an evolved universal terrestrial radio access network (E-UTRAN), also known as a long-term evolution (LTE) radio access network, and an evolved packet core, also known as a system structure evolution (SAE) core network. (EPS) is included. E-UTRAN / LTE is a variant of a 3GPP radio access network in which the radio network node is directly connected to the EPC core network rather than the RNC. Generally, in E-UTRAN / LTE, the functions of RNC are distributed between the wireless network node (eNodeB in LTE) and the core network. Therefore, the EPS RAN has an essentially "flat" architecture that includes wireless network nodes directly connected to one or more core networks, i.e. they are not connected to the RNC. To compensate for this, the E-UTRAN specification defines a direct interface between wireless network nodes, which interface is called the X2 interface. EPS is an evolved 3GPP packet-switched domain.

Advanced antenna system (ASS) is a technology that has evolved remarkably in recent years, and is a field in which rapid technological development is expected in the future. Therefore, it is natural to assume that it is generally ASS, specifically that a large number of other output multi-input (MIMO) transmissions and receptions will be the basis for future 5th generation (5G) cellular communication systems. That is.

In connection with AAS, beamforming is becoming more and more popular, not only for the transfer of data, but also for the transfer of control information. This is one motivation behind control channels in LTE, known as Enhanced Physical Downlink Control Channels (ePDCCH). When the control channel is beamformed, the additional antenna gain provides more link budgets, which can reduce the cost of transmitting overhead control information.

Automatic repeat request (ARQ) is an error control technique used in many wireless networks. With an ARQ, the receiver of the data transmission sends an acknowledgment (ACK) or a negative response (NACK) to inform the transmitter whether each message was received correctly. Messages that are received incorrectly, as well as messages that are not confirmed at all, can be resent.

Hybrid ARQ (HARQ) combines forward error correction (FEC) coding of data messages with ARQ to improve the ability to receive and correctly decode transmitted messages. As in the case of conventional ARQ, the receiver using HARQ appropriately transmits ACK and NACK each time it tries to decrypt the message. These ACKs and NACKs are referred to as "HARQ feedback".

For downlink HARQ transmissions in LTE today, HARQ feedback depends on whether a wireless device, such as a user device (UE), schedules uplink PUSCH transmissions, the physical uplink control channel (PUCCH). ) Or the physical uplink shared channel (PUSCH), transmitted from the wireless device to the network. The NW then sends feedback on an individual HARQ process basis, based on the ACK or NACK received, or if downlink (DL) allocation reception fails, i.e. the wireless device sends feedback, also known as discontinuous transmission (DTX). If not, a conclusion can be drawn as to whether the final HARQ reception for the process was successful.

The timing of HARQ feedback transmitted in LTE is 4 milliseconds in total for DL data transmission corresponding to the process in the uplink (UL) in subframe n + 4 for Frequency Division Duplex (FDD). If it is the subframe n corresponding to (ms), it is like receiving feedback from one HARQ reception (RX) process. For time-divided duplex (TDD), the delay from DL data transmission to UL feedback reception may be greater than 4 to satisfy the half-duplex DL-UL split.

Providing feedback as in the prior art can limit the performance of wireless communication networks.

Here, an object of the present invention is to provide a mechanism for improving the performance of a wireless communication network.

According to the present embodiment, the object is achieved by a method performed by the wireless network node for processing data transmission from the wireless device to the wireless network node in the wireless communication network. A wireless network node provides one or more resources to carry uplink data transmissions on a channel from a wireless device and to carry feedback transmissions of downlink data transmissions from a wireless network node on the same channel. Schedule. The wireless network node also sends a control message to the wireless device. Here, the control message indicates one or more resources scheduled to carry uplink data transmissions and feedback transmissions on the same channel.

According to the present embodiment, the object is achieved by a method performed by a wireless device to process data transmission to a wireless network node in a wireless communication network. The wireless device receives a control message from the wireless network node. Here, the control message indicates one or more resources scheduled to carry the uplink data transmission on the channel and the feedback transmission on the same channel. Feedback transmission is for downlink data transmission from a wireless network node. The wireless device uses one or more resources indicated in the control message to perform uplink data transmission and feedback transmission to the wireless network node on the same channel.

According to the present embodiment, the object is further achieved by providing a wireless network node for processing data transmission from a wireless device to a wireless network node in a wireless communication network. A wireless network node provides one or more resources to carry uplink data transmissions on a channel from a wireless device and to carry feedback transmissions of downlink data transmissions from a wireless network node on the same channel. Configured to schedule. The wireless network node is further configured to send control messages to the wireless device. Here, the control message indicates one or more resources scheduled to carry uplink data transmissions and feedback transmissions on the same channel.

According to the present embodiment, by a wireless device for processing data transmission to a wireless network node in a wireless communication network. The purpose is further achieved. The wireless device is configured to receive control messages from the wireless network node. Here, the control message indicates one or more resources scheduled to carry the uplink data transmission on the channel and to carry the feedback transmission on the same channel, where the feedback transmission is a wireless network node. It is for sending downlink data from. The wireless device is further configured to perform uplink data transmission and feedback transmission to the wireless network node on the same channel using one or more resources indicated in the control message.

Further, when executed on at least one processor, a computer program is provided that includes instructions that cause at least one processor to perform any of the above methods performed by a wireless network node or wireless device. When run on at least one processor, a computer program is stored on it that contains instructions that cause at least one processor to perform a method by any of the above methods performed by a wireless network node or wireless device. Further computer readable storage media are provided.

The present embodiment provides a method that enables feedback of DL data transmission to a wireless network node in an efficient manner. By scheduling UL data and feedback transmissions in the same control message, eg, the control portion of the message, such as control information or the same UL grant, feedback is an efficient way to reach the improved performance of the wireless communication network. Returned to the wireless network node. Since there is no puncture in this embodiment, a bit error is not introduced into a channel such as PUSCH by feedback transfer. Since both UL data transmission and feedback transmission are scheduled within the same control message, the problem of losing grants, which can cause the multiplexing method to fail, is also avoided.

Hereinafter, embodiments will be described in more detail in relation to the accompanying drawings.
FIG. 1 is an overview showing a wireless communication network according to the present embodiment. FIG. 2 is a combined flowchart and signaling scheme according to the present embodiment. FIG. 3 is a schematic flowchart showing a method performed by a wireless network node according to this embodiment. FIG. 4 is a flowchart showing a method performed by a wireless device according to the present embodiment. FIG. 5 is a block diagram showing a wireless network node according to the present embodiment. FIG. 6 is a block diagram showing a communication device according to the present embodiment.

The present embodiment generally relates to a wireless communication network. FIG. 1 is a schematic view showing a wireless communication network 1. The radio communication network 1 includes one or more RANs and one or more CNs. Wireless communication network 1 is Wi-Fi, LTE, LTE Advanced, NR (New Radio), 5G, WCDMA, GSM / EDGE (enhanced data for GSM evolution) simply to describe some possible implementations. , WiMax (Worldwide Interoperability for Microwave Access), or UMB (Ultra Mobile Broadband), several different technologies can be used. Although the present embodiment relates to recent technological trends of particular interest in the context of 5G, the embodiment is also applicable to the further development of existing wireless communication systems such as WCDMA and LTE.

In the wireless communication network 1, one or more wireless devices such as mobile stations, non-access point (non-AP) STAs, STAs, user devices, and / or wireless terminals and / or wireless terminals such as wireless terminals 10 are RANs and the like. It is possible to communicate with one or more core networks (CN) via its access network (AN). For those skilled in the art, a "wireless device" is any terminal, wireless communication terminal, user device, machine type communication (MTC) device, device-to-device (D2D) terminal, or node, smartphone, laptop. It should be understood that it is a non-limiting term meaning a node such as a mobile phone, a sensor, a repeater, a mobile tablet, or a small base station communicating in a cell.

The wireless communication network 1 is a wireless network node 12 that provides wireless coverage over a geographical area, and a service also called a beam or beam group of a first wireless access technology (RAT) such as NR, 5G, LTE, Wi-Fi. Includes area 11. The wireless network node 12 includes a wireless local area network (WRAN) access point or access point station (AP STA), an access controller, a node B, an evolved node B (eNB, eNodeB), a wireless base station, a wireless remote unit, and access. Depending on the point base station, base station router, transmission configuration of the radio base station, base station such as a radio base station such as a stand-alone access point, or, for example, the term used with the first radio access technology, the radio network node 12 It may be any other network unit capable of communicating with wireless devices in the service area served by. The wireless network node 12 is called a serving wireless network node, and communicates with the wireless device 10 by downlink (DL) transmission to the wireless device 10 and uplink (UL) transmission from the wireless device 10.

Problems have been identified as part of developing this embodiment. For example, in LTE, UL scheduling and DL feedback information, such as DL HARQ messages transmitted by UL, are separated. This was previously controlled by a fixed timing requiring DL-HARQ scheduling to be transmitted in 4 subframes after the corresponding DL data transmission was received, while UL scheduling was performed from the wireless network node 12. It means that it is processed through the UL grant of.

If the PUSCH transmission is not scheduled, the HARQ transmission is performed on the PUCCH. However, if the PUSCH is scheduled, the HARQ transmission is instead moved to the PUSCH and punctured "on" the UL data, such as the PUSCH data. Puncturing destroys some of the PUSCH transmit bits, but the PUSCH transmit bits can still be recovered by error correction mechanisms.

The reason for using puncturing instead of multiplexing is that the radio device 10 does not receive grants for UL data transmission or downlink control information (DCI) for DL data transmission. This is because it avoids. Decryption at the wireless network node is actually done by the wireless device and the wireless network node if one or the other is lost, that is, not received correctly or decrypted correctly, or if the information was multiplexed. Fails because there is a discrepancy in what was included in the transmission.

According to this embodiment, the wireless device 10 may have data for transmission to the wireless network node 12. The wireless network node 12 schedules one or more resources for the wireless device 10 to carry UL data transmissions from the wireless device 10 and to carry feedback transmissions of DL data transmissions from the wireless network node 12. .. After that, information about scheduling is transmitted to the wireless device 10.

The wireless device 10 provides feedback information such as HARQ feedback for UL data transmission and DL data transmission from the wireless network node 12 on the PDSCH, for example. The feedback information may be transmitted as part of the uplink control information (UCI) on the PUSCH as scheduled by the wireless network node 12. For example, UL data and feedback information are multiplexed into, for example, PUSCH and transmitted to the wireless network node 12.

Therefore, the present embodiment provides a mechanism for efficiently setting the configuration of feedback information when providing scheduling information for UL data transmission from the wireless device 10. Since puncturing is not performed, in this embodiment, bit errors are not introduced into PUSCH by, for example, HARQ transmission. Also, since both UL data and feedback information are scheduled for the same UL grant or the same control message, there is no problem with lost grants where the multiplexing scheme can fail.

FIG. 2 is a combined flowchart and signaling scheme according to the present embodiment. The following actions can be performed in any suitable order.

[Action 201]
The wireless device 10 has data intended to be transmitted to the wireless network node 12 or another node or wireless device. The wireless device 10 may transmit a UL data request marked with a dotted arrow when the data is buffered for transmission on the wireless device 10. Alternatively or additionally, the wireless device 10 may receive a request from the wireless network node 12 requesting UL data transmission from the wireless device 10.

[Action 202]
The wireless network node 12 schedules one or more resources, such as subframes, resource elements, resource blocks, symbols or frequencies, to carry UL data transmissions from the wireless device 10 over channels such as PUSCH. Further, the wireless network node 12 schedules one or more resources for carrying feedback transmission of DL data transmission from the wireless network node 12 from the wireless device 10.

[Action 203]
The wireless network node 12 then transmits a control message or information, such as a UL grant, indicating the scheduling of one or more resources to carry UL data transmissions from the wireless device 10 on the channel. The same control message further indicates scheduling of one or more resources for feedback transmission of DL data transmission from the wireless network node 12. UL data transmission and feedback transmission are carried on the same channel such as PUSCH. Therefore, the present embodiment discloses the transmission of UL data and feedback scheduling such as UCI in one UL grant. The feedback indicator of the feedback information can include one bit to indicate the presence of ACK / NACK, and which resource element is present can be given by the standard.

In some embodiments, the quality of channel estimation is relative to ACK / NACK because feedback indicators such as ACK / NACK, if present, are mapped to resources such as the resource element closest to the demodulation reference signal. Best and more important than other types of UCI such as Channel Quality Indicator (CQI) and Rank Indicator (RI). The data is then rate matched, i.e. mapped around these resource elements, to avoid resource elements used for feedback indicators.

In some embodiments, the scheduling command in the control message to include the ACK or NACK is greater than one bit, indicating the presence of the feedback indicator and adding the feedback indicator to the subband of the entire scheduled frequency band. Make it possible. Therefore, the feedback information or indicator does not have the same transmission band as the UL data transmission. By doing so, the scheduler at the wireless network node 12 allocates resources for feedback transmission in the subband of several possible subbands in which channel fading in the frequency domain is preferred, the so-called fading peak. can do. The advantage is better reception and more robustness of feedback information.

Thus, the present embodiment can allow PUSCH transmission that can be rate matched to available resources, and the coding rate, i.e., the amount of redundancy added, is, for example, the signal-to-noise ratio (SINR) and It means that it is configured to meet the expected channel conditions such as the number of bits available for transmission to obtain the target error probability.

[Action 204]
The wireless network node 12 transmits DL data to the wireless device 10 in DL data transmission.

[Action 205]
The wireless device 10 decodes the received DL data, for example, ACK when the decoding is successful, NACK when the data decoding fails, and discontinuous transmission (DTX), that is, for decoding control information. Attempts to generate feedback information regarding untransmitted decoding if it fails, i.e., if it does not detect a DL grant for DL data transmission.

[Action 206]
The wireless device 10 then transmits the UL data and the generated feedback information on the same channel, such as PUSCH, as scheduled in the control message.

[Action 207]
The wireless network node 12 reads the feedback information based on the knowledge of one or more scheduled resources for the feedback. The wireless network node 12 also reads the UL data transmission.

[Action 208]
The wireless network node 12 then determines whether to retransmit any DL data based on the read feedback.

FIG. 3 is a flowchart showing a method executed by the wireless network node 12 that processes data transmission such as data transmission via a subframe from the wireless device 10 to the wireless network node 12 in the wireless communication network 1. The actions are performed in any suitable order, and the optional actions are indicated by a dotted square.

[Action 301]
The wireless network node 12 may receive a UL data request from the wireless device 10, or may request UL data from a wireless network node 12 requesting measurement data from, for example, a wireless device or the like.

[Action 302]
The wireless network node 12 is to carry the uplink data transmission from the wireless device 10 on a channel such as PUSCH and to carry the feedback transmission of the downlink data transmission from the wireless network node 12 on the same channel. Schedule one or more resources.

[Action 303]
The wireless network node 12 transmits a control message to the wireless device 10. The control message indicates one or more resources scheduled to carry uplink data and feedback transmissions on the same channel. Thus, the control message indicates the scheduling of resources to carry the data transmission on the channel from the wireless device 10, and the control message further indicates the data transmission (DL data) from the wireless network node 12 on the same channel. Shows resource scheduling for feedback transmission. The control message can be an uplink grant.

[Action 304]
The wireless network node 12 then reads the feedback information received on the channel as scheduled.

[Action 305]
The wireless network node 12 then determines whether to retransmit the DL data of the downlink data transmission based on the read feedback information.

FIG. 4 is a flowchart showing a method executed by the wireless device 10 for processing data transmission (UL data) to the wireless network node 12 in the wireless communication network 1. The actions are performed in any suitable order, and the optional actions are indicated by a dotted square.

[Action 400]
The wireless device 10 can have data for the wireless network node 12 or for transmission to another node or wireless device. The wireless device 10 then transmits a UL data request, such as a UL scheduling request (SR), to the wireless network node 12, which indicates the UL data transmission from the wireless device 10. UL data transmission may also be requested from the wireless network node 12.

[Action 401]
The wireless device 10 receives a control message from the wireless network node 12. Here, the control message indicates one or more resources scheduled to carry the uplink data transmission on the channel and to carry the feedback transmission on the same channel, where the feedback transmission is a wireless network node. It is for transmitting downlink data from 12. The control message can be a UL grant. The control message may then indicate scheduling of resources to carry data transmissions from the wireless device 10 over the channel. In addition, the control message may further indicate the scheduling of resources for feedback transmission on the channel of one or more data transmissions from the wireless network node 12.

[Action 402]
The wireless device 10 receives DL data transmission from the wireless network node 12, such as some subframes carrying data information and control information / parts.

[Action 403]
The wireless device 10 generates feedback information of the received data transmission in response to the feedback transmission, such as adding a feedback indicator to the feedback message.

[Action 404]
The wireless device 10 uses one or more resources indicated in the control message to perform uplink data transmission and feedback transmission to the wireless network node 12 on the same channel. Therefore, the wireless device 10 transmits UL data to the wireless network node 12 as scheduled, and also transmits feedback of DL data transmission, such as a feedback indicator, to the wireless network node 12 in a control message as scheduled. To do. The wireless device 10 multiplexes the feedback information with the uplink data of the uplink data transmission on the same channel, so that, for example, the feedback indicator / information is multiplexed with the UL data on a channel such as a shared channel such as PUSCH. Therefore, uplink data transmission and feedback transmission to the wireless network node 12 can be performed.

FIG. 5 is a block showing the wireless network node 12 in two embodiments for processing data transmission such as UL data transmission of data via a subframe from the wireless device 10 to the wireless network node 12 in the wireless communication network 1. It is a figure.

The wireless network node 12 may have a processing unit 501, such as one or more processors, configured to perform the method.

The wireless network node 12 may have a receiver module 502 such as a receiver or transmitter. The wireless device 12, the processing module 501 and / or the receiving module 502 can be configured to receive UL scheduling requests from the wireless device 10.

The wireless network node 12 may have a scheduling module 503 such as a scheduler. The wireless network node 12, the processing unit 501, and / or the scheduling module 503 is for carrying uplink data transmissions from the wireless device 10 on the channel and for downlink data transmissions from the wireless network nodes on the same channel. It is configured to schedule one or more resources to carry feedback transmissions.

The wireless network node 12 may have a transmission module 504 such as a transmitter or transmitter / receiver. The wireless network node 12, the processing unit 501, and / or the transmission module 504 are configured to transmit control messages to the wireless device 10. Here, the control message indicates one or more resources scheduled to carry uplink data transmissions and feedback transmissions on the same channel. The control message can be an uplink grant. Also, the channel can be PUSCH.

The wireless network node 12 may have a read module 505. The wireless device 12, the processing module 501, and / or the reading module 505 may be configured to read the feedback information received on the channel as scheduled.

The wireless network node 12 may have a decision module 506. The wireless network node 12, the processing unit 501, and / or the determination module 506 may be configured to determine whether to retransmit the downlink data of the downlink data transmission based on the read feedback information.

Each of the methods according to the embodiments described herein for a wireless network node 12 is such that, when executed on at least one processor, it is executed by the wireless network node 12 on that at least one processor. It is implemented by means such as a computer program 507 or a computer program product that includes an instruction to execute the described action, i.e. a software code portion. The computer program 507 can be stored in a computer-readable storage medium 508 such as a disk or USB. A computer-readable storage medium 508 stores a computer program and is described herein such that when executed on at least one processor, it is executed by the wireless network node 12 on that at least one processor. It can contain instructions to execute an action. In some embodiments, the computer-readable storage medium can be a non-temporary computer-readable storage medium.

The wireless network node 12 may further have memory 509. Memory includes one or more units used to store data, such as feedback indicators, resources, SR, DL data, UL grants, applications for performing the methods disclosed herein at run time. Therefore, in the wireless communication network 1, a first wireless network node 12 for processing data transmission from the wireless device 10 to the wireless network node 12 may be provided here, and the memory 509 is provided by the processing unit 501. Includes executable instructions, whereby the first wireless network node 12 operates to perform the method.

FIG. 6 is a block diagram showing a wireless device 10 in two embodiments for processing data transmission (UL data) to the wireless network node 12 in the wireless communication network 1.

The wireless device 10 may have a processing unit 601 such as one or more processors configured to perform the method.

The wireless device 10 may have a transmitter module 602 such as a transmitter or transmitter / receiver. The wireless device 10, the processing unit 601 and / or the transmission module 602 may have a wireless device 10 such as an SR if the wireless device 10 has data for the wireless network node 12 or data for transmission to another node or wireless device. A UL data request indicating UL data transmission from is transmitted to the wireless network node 12.

The wireless device 10 may have a receiver module 603 such as a receiver or transmitter / receiver. The wireless network node 10, the processing unit 601 and / or the receiving module 603 are configured to receive control messages from the wireless network node 12. Here, the control message indicates one or more resources scheduled to carry the uplink data transmission on the channel and the feedback transmission on the same channel. The feedback transmission is for downlink data transmission from the wireless network node 12. The control message may indicate scheduling of resources to carry data transmissions on the channel from the wireless device 10. In addition, the control message may indicate the scheduling of resources for feedback transmission on the channel of one or more data transmissions from the wireless network node 12.

The wireless device 10, the processing unit 601 and / or the receiving module 603 are configured to receive DL data transmissions such as some subframes carrying data information and control parts / information from the wireless network node 12. obtain.

The wireless device 10 may have a generation module 604. The wireless device 10, the processing unit 601 and / or the generation module 604 may be configured to generate feedback information for the received data transmission in response to the feedback transmission, such as adding a feedback indicator to the feedback message.

The wireless device 10 may have a multiplexing module 605. The wireless device 10, the processing unit 601 and / or the multiplexing module 605 may be configured to multiplex feedback such as feedback indicators / information with UL data on channels such as shared channels such as PUSCH. Therefore, the wireless device 10. The processing unit 601 and / or the multiplexing module 605 executes the uplink transmission and the feedback transmission on the same channel by configuring the feedback information to be multiplexed with the uplink data of the uplink data transmission. Can be configured as

The wireless device 10, the processing unit 601 and / or the transmission module 602 use one or more resources indicated in the control message to perform uplink data transmission and feedback transmission to the wireless network node 12 on the same channel. It is configured to do. Therefore, the wireless device 10, the processing unit 601 and / or the transmission module 602 transmits UL data to the wireless network node 12 as scheduled and feedback of DL data transmission, eg, feedback, as scheduled. The indicator may be configured to send to the wireless network node 12 in a control message. The channel can be a physical uplink shared channel. Also, the control message can be an uplink grant.

Each of the methods for a wireless device 10 according to the embodiments described herein, when executed on at least one processor, causes the at least one processor to perform the actions described herein such that it is performed by the wireless device 10. It is implemented by means such as a computer program 606 or a computer program product that includes an instruction to be executed, i.e. a software code portion. The computer program 606 can be stored in a computer-readable storage medium 607 such as a disk or USB. The computer-readable storage medium 6607 stores a computer program, and when executed on at least one processor, the actions described herein are such that the at least one processor is executed by the wireless device 10. Can include instructions to execute. In some embodiments, the computer-readable storage medium can be a non-temporary computer-readable storage medium.

The wireless device 10 may further have a memory 608. Memory contains one or more units used to store data, such as feedback indicators, resources, multiplexing, SR, DL data, UL grants, applications for performing the methods disclosed herein at run time, etc. Including.

Therefore, in the wireless communication network 1, the wireless device 10 for processing the data transmission (UL data) to the wireless network node 12 may be provided here, and the memory 608 is an instruction that can be executed by the processing unit 601. The wireless device 10 thereby operates to perform the method.

As easily understood by those familiar with communication design, functional means or modules may be implemented using digital logic and / or one or more microcontrollers, microprocessors, or other digital hardware. .. In some embodiments, some of the various features, such as a single application specific integrated circuit (ASIC), or two or more separate devices with suitable hardware and / or software interfaces between them. Or everything can be implemented together. Some features may be implemented, for example, on a processor shared with other functional components of the wireless network node.

Alternatively, some functional elements of the described processing means may be provided using dedicated hardware, for other software to run the software in connection with the appropriate software or firmware. Hardware may be provided. Therefore, the term "processor" or "controller" used here does not exclusively refer to hardware capable of executing software, but is used to store digital signal processor (DSP) hardware and software. Includes read-only memory (ROM), random access memory for storing software and / or program or application data, and non-volatile memory. Other traditional and / or custom hardware can also be included. Designers of wireless network nodes will understand the cost, performance, and maintenance trade-offs inherent in these design choices.

Here, a method performed by a wireless network node for processing data transmission, such as data transmission via a subframe, from a wireless device to a wireless network node in a wireless communication network is disclosed. The wireless network node sends a control message indicating the scheduling of resources to carry data transmission over the channel from the wireless device, eg UL grant, and the control message is from the wireless network node over the same channel. Includes feedback transmission of data transmission.

Further disclosed is a method performed by a wireless device for processing data transmission to a wireless network node in a wireless communication network. The wireless device receives control messages from the wireless network node. The control message indicates the scheduling of resources for carrying data transmissions on the channel from the wireless device, and the control message further indicates the scheduling of resources for feedback transmission of data transmissions from the wireless network node on the same channel. .. The wireless device then transmits the data as scheduled and also transmits a feedback indicator for DL data transmission as scheduled to the wireless network node 12j in the control message.

Additionally, wireless network nodes and wireless devices configured to perform this method are also provided.

Further, when executed on at least one processor, a computer program is provided that includes instructions that cause at least one processor to perform any of the above methods performed by a wireless network node or wireless device. When run on at least one processor, a computer program is stored on it that contains instructions that cause at least one processor to perform a method by any of the above methods performed by a wireless network node or wireless device. Further computer readable storage media are provided.

It will be appreciated that the above description and accompanying drawings represent non-limiting examples of the methods and devices taught herein. Therefore, the devices and techniques taught herein are not limited by the above description and accompanying drawings. Alternatively, this embodiment is limited only by the appended claims and their legal equivalents.

Claims (15)

A method performed by the wireless network node for processing data transmission from the wireless device (10) to the wireless network node (12) in the wireless communication network (1).
One or more resources for carrying uplink data transmissions on a channel from the wireless device (10), and one for carrying feedback transmissions of downlink data transmissions from the wireless network node on the same channel. Scheduling one or more resources (302) and
Sending a single control message to the wireless device (10) (303), wherein the single control message is the one or more resources scheduled to carry the uplink data transmission. , And the one or more resources scheduled for the feedback transmission on the same channel.
Reading the feedback information received on the channel as scheduled (304), the feedback information is the uplink data of the uplink data transmission and the uplink data on the same channel. A method that involves multiplexing the bits of transmission without puncturing. The method according to claim 1, further
A method comprising determining (305) whether or not to retransmit the downlink data of the downlink data transmission based on the read feedback information. The method of claim 1 or 2, wherein the single control message is an uplink grant and the channel is a physical uplink shared channel. A method performed by a wireless device (10) for processing data transmission to a wireless network node (12) in a wireless communication network (1).
Receiving a single control message from the wireless network node (12) (401), wherein the single control message is one or more scheduled to carry uplink data transmissions on the channel. And one or more resources scheduled to carry feedback transmissions on the same channel, said feedback transmissions for downlink data transmissions from said wireless network node (12). There is, that,
Using the resource indicated in the control message to execute the uplink data transmission and the feedback transmission to the wireless network node (12) on the same channel (404), the uplink data. Performing the transmission and the feedback transmission includes multiplexing the feedback information with the uplink data of the uplink data transmission and the bits of the uplink data transmission without puncturing on the same channel. , Including methods. The method according to claim 4, further
Receiving the downlink data transmission from the wireless network node (12) (402) and
A method comprising generating feedback information of the received data transmission with respect to the feedback transmission (403). The method of claim 4 or 5, wherein the channel is a physical uplink shared channel and the control message is an uplink grant. A wireless network node (12) for processing data transmission from a wireless device (10) to a wireless network node (12) in a wireless communication network (1).
One or more resources for carrying uplink data transmissions on a channel from the wireless device (10), and one for carrying feedback transmissions of downlink data transmissions from the wireless network node on the same channel. Schedule one or more resources and
A single control message is transmitted to the wireless device (10), wherein the single control message is the one or more resources scheduled to carry the uplink data transmission, and said. Indicates the one or more resources scheduled to carry the feedback transmission on the same channel.
The feedback information received on the channel is read as scheduled, where the feedback information includes the uplink data of the uplink data transmission and the bits of the uplink data transmission on the same channel. A wireless network node configured to be multiplexed without puncturing. The wireless network node (12) according to claim 7, wherein the feedback information is not punctured by the uplink data of the uplink data transmission on the same channel. The wireless network node (12) according to claim 7 or 8, further
A wireless network node configured to determine whether to retransmit the downlink data of the downlink data transmission based on the read feedback information. The wireless network node (12) according to any one of claims 7 to 9, wherein the single control message is an uplink grant, and the channel is a physical uplink shared channel. .. A wireless device (10) for processing data transmission to a wireless network node (12) in a wireless communication network (1).
A single control message is received from the wireless network node (12), where the single control message is one or more resources scheduled to carry uplink data transmissions over the channel, and Indicates one or more resources scheduled to carry feedback transmissions on the same channel, said feedback transmission is for downlink data transmission from said wireless network node (12).
On the same channel, the feedback information is configured to multiplex the uplink data of the uplink data transmission and the bits of the uplink data transmission without puncturing, thereby forming the single control message. A wireless device configured to perform the uplink data transmission and the feedback transmission to the wireless network node (12) on the same channel using the indicated resources. The wireless device (10) according to claim 11, further
Upon receiving the downlink data transmission from the wireless network node (12),
A wireless device configured to generate feedback information for the received data transmission in response to the feedback transmission. The wireless device (10) according to claim 11 or 12, wherein the channel is a physical uplink shared channel and the control message is an uplink grant. The method according to any one of claims 1 to 6, which is a computer program and is executed by the wireless device (10) or the wireless network node (12) when executed by at least one processor. A computer program comprising instructions to be executed by at least one of the processors. The method according to any one of claims 1 to 6, which, when executed on at least one processor, is executed by the wireless device (10) or wireless network node (12) on the at least one processor. A computer-readable storage medium that contains a computer program that contains instructions to execute.

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